Y. Lahbib-Mansais

A somatic cell hybrid panel for pig regional gene mapping characterized by molecular cytogenetics.

A panel of 27 pig x rodent somatic cell hybrids was produced and characterized cytogenetically. The first step of this study consisted of hybridizing a SINE probe to GTG-banded metaphases of each hybrid clone in order to count and identify the normal pig chromosomes and to detect rearranged ones. The second step consisted of using the DNA of each clone as a probe after pIRS-PCR (porcine interspersed repetitive sequence-polymerase chain reaction) amplification to highly enrich it in pig sequences. These probes, hybridized to normal pig metaphase chromosomes, enabled the identification of the complete porcine complement in the hybrid lines. Whole chromosomes and fragments were characterized quickly and precisely, and results were compared. In addition to this cytogenetic characterization, molecular verification was also carried out by using primers specific to six microsatellites and to one gene previously mapped to pig chromosomes. The results obtained allow us to conclude that we have produced a panel that is informative for all porcine chromosomes. This panel constitutes a highly efficient tool to establish not only assignments of genes and markers but also regional localizations on pig chromosomes.

The PiGMaP consortium cytogenetic map of the domestic pig (Sus scrofa domestica)

llNRA, Laboratoire de Grnrtique Cellulaire, BP27, 31326 Castanet-Tolosan, France 2Department of Functional Morphology, Faculty of Veterinary Medicine, Utrecht University, Utrecht, The Netherlands 3Department of Animal Breeding and Genetics, Swedish University of Agricultural Sciences, Uppsala, Sweden 4Division of Anatomy, Department of Anatomy and Physiology, The Royal Veterinary and Agricultural University, Copenhagen, Denmark 5Division of Animal Genetics, Department of Animal Science and Animal Health, The Royal Veterinary and Agricultural University, Copenhagen, Denmark 6Department of Clinical Genetics, University of Ulm, Ulm, Germany 7Laboratoire de Cytomrtrie, CEA, Fontenay-aux Roses, France

Porcine linkage and cytogenetic maps integrated by regional mapping of 100 microsatellites on somatic cell hybrid panel

Recently two main genetic maps [Rohrer et al. Genetics 136, 231 (1994); Archibald et al. Mamm. Genome 6, 157 (1995)] and a cytogenetic map [Yerle et al. Mamm. Genome 6,175 (1995)] for the porcine genome were reported. As only a very few microsatellites are located on the cytogenetic map, it appears to be important to increase the relationships between the genetic and cytogenetic maps. This document describes the regional mapping of 100 genetic markers with a somatic cell hybrid panel. Among the markers, 91 correspond to new localizations. Our study enabled the localization of 14 new markers found on both maps, of 54 found on the USDA map, and of 23 found on the PiGMaP map. Now 21% and 43% of the markers on the USDA and PiGMaP linkage maps respectively are physically mapped. This new cytogenetic information was then integrated within the framework of each genetic map. The cytogenetic orientation of the USDA linkage maps for Chromosomes (Chrs) 3, 8, 9, and 16 and of PiGMaP for Chr 8 was determined. USDA and PiGMaP linkage maps are now oriented for all chromosomes, except for Chrs 17 and 18. Moreover, the linkage group “R” from the USDA linkage map was assigned to Chr 6.

Accurate mapping of the “acid meat” RN gene on genetic and physical maps of pig Chromosome 15

It has been shown that a major gene, called RN, is responsible for the RTN technological yield, a meat quality porcine trait. Experimental families informative for the segregation of RN gene were constituted from animals belonging to the Laconie composite line. We have previously mapped the RN gene to Chromosome (Chr) 15 (Milan et al. Genet. Sel. Evol. 27, 195-199, 1995). A Chr 15 map was established with 16 markers. The RN gene was found to be located between markers Sw120 and Sw936, at 2 cM from Sw936 (LOD = 38.1). In addition, by localizing Sw936 at 15q21–22 using DISC-PCR, we also located RN on the physical map.

NEMO: a tool for analyzing gene and chromosome territory distributions from 3D-FISH experiments

UNLABELLED Three-dimensional fluorescence in situ hybridization (3D-FISH) is used to study the organization and the positioning of chromosomes or specific sequences such as genes or RNA in cell nuclei. Many different programs (commercial or free) allow image analysis for 3D-FISH experiments. One of the more efficient open-source programs for automatically processing 3D-FISH microscopy images is Smart 3D-FISH, an ImageJ plug-in designed to automatically analyze distances between genes. One of the drawbacks of Smart 3D-FISH is that it has a rather basic user interface and produces its results in various text and image files thus making the data post-processing step time consuming. We developed a new Smart 3D-FISH graphical user interface, NEMO, which provides all information in the same place so that results can be checked and validated efficiently. NEMO gives users the ability to drive their experiments analysis in either automatic, semi-automatic or manual detection mode. We also tuned Smart 3D-FISH to better analyze chromosome territories. AVAILABILITY NEMO is a stand-alone Java application available for Windows and Linux platforms. The program is distributed under the creative commons licence and can be freely downloaded from https://www-lgc.toulouse.inra.fr/nemo

A successful strategy for comparative mapping with human ESTs: 65 new regional assignments in the pig

Abstract. Large-scale sequencing of cDNAs from numerous tissues is currently being performed within the framework of the Human Genome Project. These expressed sequence tags (ESTs) are then mapped on a radiation hybrid panel to produce a high-resolution map of human genes. In this report, we estimate the efficiency of mapping these ESTs in the pig. A total of 344 human ESTs from Généthon were selected for amplification in other species by Zoo-PCR: 186 of these could be reproducibly amplified by use of pig DNA and the corresponding human primer pairs. One-hundred seven of these were tested on a porcine–rodent somatic cell hybrid panel, permitting regional localizations of 65 ESTs with agarose or single-strand conformation polymorphism analysis gels. The corresponding pig PCR products were sequenced: 60 ESTs matched significantly with the expected human sequences. Fifty-one of these localizations in the pig are in agreement with the comparative mapping data between humans and pigs based on heterologous chromosome painting. Seven ESTs that were localized in an unexpected region may indicate new chromosomal correspondences. This work significantly increases the number of genes mapped on the pig genome and demonstrates that this approach can be successfully applied to improve the gene density of mammalian genomic maps in chromosomal regions of interest, such as those in which QTL (Quantative Trait Loci) have been identified.

Localization of the pig luteinizing hormone/choriogonadotropin receptor gene (LHCGR) by radioactive and nonradioactive in situ hybridization

The porcine gene for luteinizing hormone/choriogonadotropin receptor (LHCGR) was localized to chromosome 3q2.2----q2.3 using radioactive and nonradioactive in situ hybridization. A computer-assisted image-analysis system was developed which facilitated detection of the position of silver grains and fluorescent spots on the chromosomes after in situ hybridization. Compared with autoradiographic visualization, the nonisotopic procedure proved to be more rapid, precise, and highly specific; however, nonradiographic in situ hybridization was much less efficient than the autoradiographic technique for the detection of unique DNA sequences with small probes. From these results and published gene-mapping data, it was concluded that the synteny between LHCGR and MDH1 observed in man is conserved in the pig genome.

Contribution to high-resolution mapping in pigs with 101 type I markers and progress in comparative map between humans and pigs.

In the frame of the European program GenetPig, we localized on the Pig map 105 coding sequences (type I markers) from different origins, using INRA-University of Minnesota porcine Radiation Hybrid Panel (IMpRH, 101 markers) and somatic cell hybrid panel (SCHP, 93 markers, of which only four were not also mapped using IMpRH). Thus, we contributed to the improvement of the porcine high-resolution map, and we complemented the integration between the RH and cytogenetic maps. IMpRH tools allowed us to map 101 new markers relatively to reference markers of the first generation radiation hybrid map. Ninety out of 101 markers are linked to an already mapped marker with a LOD score greater than 4.8. Seventy-eight markers were informative for comparative mapping. Comparison of marker positions on the RH map with those obtained on the cytogenetic map or those expected by Human-Pig comparative map data suggested to us to be cautious with markers linked with a LOD lower than 6. These results allowed us to specify chromosomal fragments well conserved between humans and pigs and also to suggest new correspondences (Sscr1-Hsap3, Sscr9-Hsap9, Sscr13-Hsap11, Sscr15-Hsap6) confirmed by FISH on pig chromosomes. We examined in more detail the comparative map between Hsap12 and Sscr5 considering gene order, which suggests that rearrangements have occurred within the conserved synteny.

Comparative mapping between humans and pigs: localization of 58 anchorage markers (TOASTs) by use of porcine somatic cell and radiation hybrid panels

Abstract. To increase the number of Type I markers that are directly informative for comparative mapping, 58 anchorage markers, TOASTs (Traced Orthologous Amplified Sequence Tags), were mapped in pig. With specific consensus primers, 76 TOASTs were tested in pig: 50 were regionally localized in pig on a somatic cell hybrid panel (SCHP), and 51 were mapped on the whole genome, INRA/University of Minnesota porcine Radiation Hybrid panel (IMpRH). Comparison of marker positions on RH and cytogenetic maps indicated general concordance except for two chromosomal regions. For RH mapping, all markers, apart from one, were significantly linked (LOD > 4.8) to a marker of the first-generation radiation hybrid map. Localization of new markers on the initial map is necessary for drawing a framework map as shown for Chromosome Sscr 14. The addition of four TOASTs has enabled us to propose an improved map, using a threshold likelihood ratio of 1000/1. At the whole-genome level, this work significantly increased (by 50%) the number of precisely mapped genes on the porcine RH map and confirmed that the IMpRH panel is a valuable tool for high-resolution gene mapping in pig. Porcine PCR products were sequenced and compared with human sequences to verify their identity. Most of the localizations made it possible to either confirm or refine the previous comparative data between humans and pigs obtained through heterologous chromosomal painting or gene mapping. Moreover, the use of TOASTs in mapping studies appears to be a complement to other strategies using CATS, human ESTs, or heterologous FISH with BACs which had already been applied to improve the gene density of comparative genomic maps for mammals.

Conserved synteny and gene order difference between human chromosome 12 and pig chromosome 5

A comparative map of human chromosome 12 (HSA 12) and pig chromosome 5 (SSC 5) was constructed using ten pig expressed sequence tags (ESTs). These ESTs were isolated from primary granulosa cell cultures by differential display (EST b10b), or from a granulosa cDNA library (VIIIE1, DRIM, N*9, RIIID2 and RVIC1) or from a small intestine cDNA library (ATPSB, ITGB7, MYH9, and STAT2). Also used were two Traced Orthologous Amplified Sequence Tags (TOASTs) (LALBA, TRA1), one microsatellite-associated gene (IGF1) and finally five human YACs selected for their cytogenetic position, with a view to increasing the number of informative markers for the comparison. Large-insert clones were obtained by screening a pig bacterial artificial chromosome (BAC) library with specific primers for each EST and TOAST and for IGF1. These BACs were used as probes for fluorescent in situ hybridisation (FISH) both on porcine and human metaphases. In addition, the human YACs were FISH mapped on pig chromosomes. This allowed us to refine and, in some cases, to correct the previous mapping obtained with a somatic cell hybrid panel. While these data confirm chromosome painting results showing that the distal part of SSC 5p arm is conserved on HSA 22, while the rest of the chromosome corresponds to HSA 12, they also demonstrate gene-order differences between human and pig. In addition, it was also possible to determine the position of the synteny breakpoint.